KR20100084639A - Structural member joint structure - Google Patents

Abstract

A structural member joint structure can easily join members to each other by using a simple structure having a reduced number of parts and can provide the members with a large fastening force which makes the members less likely to be loosened from each other. The joint structure is used to join one pillar and the other pillar to each other such that the other member is vertically abutted against a side face of the one pillar. The structure has a pair of fastening members arranged so as to be movable in the lateral direction of a groove located on the inward side of the other pillar and formed in a side face of the one pillar, a nut mechanism located on the inward side of the other pillar and formed between the pair of fastening members, and a bolt operated from the outside through an opening in the other pillar to be fitted into the nut mechanism. Rotating the bolt causes the nut mechanism to urge and move the pair of fastening members in the direction in which the pair is separated from each other. This causes engagement projections respectively arranged on ends of the pair of fastening members to engage with engagement recesses respectively arranged at lateral opposite ends of the groove in the one pillar. Thus, the pillars are joined to each other.

Description

STRUCTURAL MEMBER JOINT STRUCTURE}

The present invention relates to, for example, a coupling structure of a structural material for joining both pillar members in a state in which the end surface of the other pillar member is orthogonal to the side surface of one pillar member, and in that state. The present invention relates to a device that is designed to be easily combined in a simple structure with a small number and to be hard to loosen with respect to external force, thereby obtaining a secure fastening force.

For example, when the cross section of the other pillar member is placed on the side surface of one pillar member from the direction orthogonal to each other, and both pillar members are joined in that state, the following coupling structure is achieved. First, the end surface of the other pillar member is brought into contact with the side surface of one pillar member, and an approximately triangular bracket is attached and fixed to the corner of the contact portion by a screw.

In addition, there are the following as a separate coupling structure. First, in the groove joint of one of the pillar members, an assembly having an end portion extending outward of the groove joint is engaged. Next, the cross section of the other pillar member is placed on the side surface of the one pillar member. And the said end of the said assembly is fixed to a predetermined position in the groove joint of the other pillar member by a screw.

According to the conventional structure as described above, there were the following problems.

First, in the first example of the related art, a bracket must be attached to each of the one pillar member and the other pillar member by screws, and there is a problem that a large number of screws are required at that time. In addition, there is a problem that a plurality of screws are required to be fastened using a fastening tool, which requires a lot of labor and a long time.

Moreover, in the case of the first example of the prior art, since the bracket is screwed in the state which attached the cross section of the other pillar member with respect to the side surface of one pillar member, the stability of both pillar members is impaired at that time, and workability There was a problem of being bad.

In addition, even in the case of the conventional second example, since the assembly is screwed in the state where the cross section of the other pillar member is attached to the side surface of one pillar member, the stability of both pillar members is impaired at that time. There was a problem of being bad.

On the other hand, as a solution to the above problems, there are inventions disclosed in Patent Document 1, Patent Document 2 and the like, for example. All of which are filed by the present patent applicant.

Japanese Patent Laid-Open No. 2002-61302 Japanese Unexamined Patent Publication No. 2007-154924

The present invention has been made on the basis of this point, and its object is to provide a structure in which a structural member can be easily attached with a simple structure having a small number of parts, and it is difficult to loosen with respect to external force, thereby obtaining a firm fastening force. To provide.

In order to achieve the above object, the coupling structure of the structural member according to claim 1 of the present invention is a coupling structure of the structural member that is coupled to the side of one pillar member in a state where the other pillar member is vertically attached, wherein the other pillar member is A pair of fastening members provided to be movable in the width direction of the groove formed in the side surface of the one pillar member at an inner side of the nut, and a nut mechanism disposed between the pair of fastening members inside the other pillar member. And a bolt which is manipulated from the outside through an opening formed in the other pillar member to be screwed to the nut mechanism, and spaces the pair of fastening members from each other by the action of the nut mechanism by rotating the bolt. In a direction, by moving the pair of The coupling convex portions respectively formed at the end of the fastening member are coupled to the coupling concave portions formed at both ends in the width direction of the groove of the one pillar member to obtain a coupling state.

Moreover, the coupling structure of the structural member of Claim 2 is a coupling structure of the structural member of Claim 1 WHEREIN: The said nut mechanism is the inside of the said other pillar member, and is arrange | positioned between the said pair of fastening members, Between a pair of intermediate pressure members provided with a pair of tapered surfaces opposing the pair of tapered surfaces of the fastening member, and provided with a tapered surface opposite thereto, and the pair of intermediate pressure members. It consists of a nut having a pair of tapered surfaces disposed opposite to each of the tapered surfaces of the pair of intermediate pressure members, the nut is pulled to the bolt side by screwing the bolt to the nut, the taper of the nut By the interaction between the surface and the tapered surface of the pair of intermediate pressure member Pressing and moving the pair of intermediate pressure members in a direction away from each other, the tapered surface of the pair of intermediate pressure members and the taper surface of the pair of fastening members by the movement of the pair of intermediate pressure members in the separation direction It is characterized in that by pressing and moving the pair of fastening members in a direction away from each other by interaction with.

In the coupling structure of the structural member according to claim 3, in the coupling structure of the structural member according to claim 2, the pair of intermediate pressure members move along the longitudinal direction of the other pillar member, whereby the pair The fastening member is characterized in that for moving along the width direction of the groove.

In the coupling structure of the structural member according to claim 4, in the coupling structure of the structural member according to claim 2 or 3, a guide groove is formed in each of the pair of intermediate pressure members, and the nut is provided in the guide groove. It is characterized in that the guide portion is installed to be movable relative to the.

In the coupling structure of the structural member according to claim 5, in the coupling structure of the structural member according to any one of claims 2 to 4, the pair of fastening members are each formed with recesses, and the tapered surface is recessed. It is formed in the portion, characterized in that the pair of intermediate pressure member and the nut is configured to be accommodated in the recess.

In the coupling structure of the structural member according to claim 6, in the coupling structure of the structural member according to claim 1, the nut mechanism is disposed inside the other pillar member and disposed between the pair of fastening members, respectively. Consists of a pair of nuts provided with the tapered surface facing each other, by moving the bolt to move the pair of nuts to the outside by the interaction of the tapered surface of the pair of nuts, thereby Pressing and moving the pair of fastening members disposed in the direction to separate from each other is characterized in that the.

In the coupling structure of the structural member according to claim 7, in the coupling structure of the structural member according to claim 6, the pair of nuts are laminated and arranged in a state in which the respective tapered surfaces are in close contact with each other along the axial direction of the bolt. By screwing the bolts, the nut arranged on the side away from the bolt is pulled to the bolt side, whereby the pair of nuts move outwards and the pair of fastening members arranged on the outside of each other are spaced apart from each other. It is characterized by moving in the direction.

In the coupling structure of the structural member according to claim 8, the coupling structure of the structural member according to claim 6 or 7, wherein the pair of fastening members are formed with coupling recesses for coupling the pair of nuts, respectively. It is.

As described above, the coupling structure of the structural member according to claim 1 of the present invention is a coupling structure of the structural member which is coupled to the side surface of one pillar member in a state in which the other pillar member is vertically attached. A pair of fastening members provided to be movable in the width direction of the groove formed in the side surface of the one pillar member inward, a nut mechanism disposed between the pair of fastening members inside the other pillar member; And a bolt which is manipulated from the outside through an opening formed in the other pillar member to be screwed to the nut mechanism, and is spaced apart from each other by the action of the nut mechanism by rotating the bolt. Pressurized, moved, and the pair of Since the coupling convex portions respectively formed at the end of the fastening member are coupled to the coupling concave portions formed at both ends in the width direction of the groove of the one pillar member, the coupling state is obtained to obtain a desired coupling state with a small number of parts. Can be. Specifically, a desired engagement state is obtained by a pair of fastening members, nut mechanisms, and bolts. Therefore, parts management is easy and cost-effective.

In addition, the bolt is screwed to the nut, and a pair of fastening members are installed in the groove so as to be covered and hidden by the other pillar member, and then the desired coupling is achieved by simply rotating the bolt through the opening of the other pillar member. Since the state is obtained, the coupling work can be facilitated, and the labor force required for the work can be reduced and the time can be shortened.

In addition, since the bolt is screwed to the nut and the pair of fastening members are installed in the grooves, they are covered and hidden by the other pillar member, thereby ensuring sufficient stability during the joining operation.

In addition, a secure engagement state can be obtained by the action of the nut mechanism and the coupling structure of the coupling convex portion of the pair of fastening members and the coupling concave portion of the groove.

Moreover, the coupling structure of the structural material of Claim 2 is a coupling structure of the structural material of Claim 1 WHEREIN: The said nut mechanism is inside of the said other pillar member, and is arrange | positioned between the said pair of fastening members, and said pair A pair of tapered surfaces facing each other and a pair of tapered surfaces facing each other and having a tapered surface opposite thereto, and the pair of intermediate pressure members It consists of a nut disposed between and having a pair of tapered surfaces facing each tapered surface of the pair of intermediate pressure members, wherein the nut is pulled to the bolt side by screwing the bolt to the nut, By the interaction between the tapered surface and the tapered surface of the pair of intermediate pressure members, Pressing and moving the pair of intermediate pressure members in a direction away from each other, the tapered surface of the pair of intermediate pressure members and the tapered surface of the pair of fastening members by the movement of the intermediate pressure member relative to the pair of separation direction Since the pair of fastening members are pressurized and moved in a direction away from each other by interaction with each other, the above-mentioned effect can be reliably obtained.

In the coupling structure of the structural member according to claim 3, in the coupling structure of the structural member according to claim 2, the pair of intermediate pressure members move along the longitudinal direction of the other pillar member, whereby the pair of Since the fastening member is configured to move along the width direction of the groove, the above effect can be obtained more reliably.

In the coupling structure of the structural member according to claim 4, in the coupling structure of the structural member according to claim 2 or 3, a guide groove is formed in each of the pair of intermediate pressure members, and the nut is provided with respect to the guide groove. Since the guide part which couples so that a movement is possible is provided, the position shift of a pair of intermediate | middle pressure member and a nut can be prevented, and the fastening operation can be made easy by this.

In the coupling structure of the structural member according to claim 5, in the coupling structure of the structural member according to any one of claims 2 to 4, the pair of fastening members are each formed with recesses, and the tapered surfaces are formed in the recesses. Since the pair of intermediate pressure members and the nut are configured to be accommodated in the concave portion, it is possible to prevent displacement and facilitate the fastening operation.

Moreover, the coupling structure of the structural member of Claim 6 is the coupling structure of the structural member of Claim 1 WHEREIN: The said nut mechanism is inside of the said other pillar member, and is arrange | positioned between the said pair of fastening members, and each is provided. Consists of a pair of nuts provided with the tapered surface facing each other, by moving the bolt to move the pair of nuts to the outside by the interaction of the tapered surface of the pair of nuts, thereby Since the pair of fastening members arranged in such a manner is pressed and moved in a direction away from each other, the effect according to claim 1 can be reliably obtained and the number of parts can be further reduced.

In the coupling structure of the structural member according to claim 7, in the coupling structure of the structural member according to claim 6, the pair of nuts are laminated and arranged in a state in which the respective tapered surfaces are in close contact with each other along the axial direction of the bolt. By screwing the bolts, the nut arranged on the side away from the bolt is pulled to the bolt side, whereby the pair of nuts move outwards and the pair of fastening members arranged on the outside of each other are spaced apart from each other. Since it is comprised as moving in a direction, the said effect can be made more reliable.

Moreover, in the coupling structure of the structural material of Claim 8, in the coupling structure of the structural material of Claim 6 or 7, WHEREIN: Since the said coupling fastening member is provided with the coupling recessed part which the said pair of nuts couple, respectively, it shifts a position. The prevention and fastening work can be facilitated.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view showing a state in which a cross section of the other pillar member is joined to a side surface of one pillar member as a view showing a first embodiment of the present invention.
FIG. 2 is a side view showing a first embodiment of the present invention in which a cross section of the other pillar member is joined to the side surface of one pillar member.
3 is an exploded perspective view showing a first embodiment of the present invention in which a cross section of the other pillar member is joined to the side surface of one pillar member.
4 is a front view showing a state in which a pair of intermediate pressure members and a nut are assembled, showing a first embodiment of the present invention.
FIG. 5 is a side view showing a first embodiment of the present invention, in which a pair of intermediate pressure members and nuts are assembled.
Fig. 6 is a diagram showing a first embodiment of the present invention, showing a state in which a cross section of the other pillar member is joined to the side surface of one pillar member, and a front sectional view for explaining the operation thereof.
Fig. 7 is a view showing a second embodiment of the present invention, and is a front view showing a state in which a cross section of the other pillar member is joined to the side surface of one pillar member.
FIG. 8 is a side view showing a second embodiment of the present invention in which a cross section of the other pillar member is joined to the side surface of one pillar member.
9 is an exploded perspective view showing a second embodiment of the present invention in which a cross section of the other pillar member is joined to the side surface of one pillar member.
Fig. 10 is an exploded front view showing a second embodiment of the present invention in which a cross section of the other pillar member is joined to the side surface of one pillar member.
FIG. 11 is a front view showing the structure of a pair of nuts, showing a second embodiment of the present invention. FIG.
Fig. 12 is a diagram showing a second embodiment of the present invention, showing a state in which a cross section of the other pillar member is joined to the side surface of one pillar member, and is a front sectional view for explaining the operation.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. First, there is one pillar member 1, and the pillar member 1 has a substantially square cross-sectional shape and a hollow shape. That is, the hollow part 3 is formed in the center part of the pillar member 1. This hollow part 3 extends and is formed along the longitudinal direction of the pillar member 1. Moreover, in the cross-sectional shape of the pillar member 1, the other hollow part 5 is formed in four corners. These four hollow parts 5 also extend and form along the longitudinal direction of the pillar member 1.

In addition, the grooves 9 are formed in the four side surfaces 7 of the pillar member 1. Engaging recesses 11 and 11 are formed at both ends in the width direction of the groove 9.

Arbitrary side surfaces 7 of the one pillar member 1 are joined in contact with each other by a direction perpendicular to the other pillar member 1 '. The other pillar member 1 ′ also has the same shape as the one pillar member 1. In the drawings, the same reference numerals are attached to the same reference numerals. Moreover, the opening part 21 is formed in the specific groove 9 'of the other pillar member 1'. Through this opening part 21, the bolt mentioned later is operated.

In a certain groove 9 of the one pillar member 1, a pair of intermediate pressure members 31 and 31 are provided in a state of facing up and down in FIG. Guide grooves 33 and 33 are formed in one of the intermediate pressure members 31 of the pair of intermediate pressure members 31 and 31. Similarly, guide grooves 33 and 33 are formed in the other intermediate pressure member 31. A tapered surface 35 is formed between the guide grooves 33 and 33. Moreover, the tapered surface 35 is provided with the recessed part 37 whose cross-sectional shape is semicircular. Further, among the pair of intermediate pressure members 31 and 31, one of the intermediate pressure members 31 is provided with other tapered surfaces 39 and 39 on the outside thereof. Similarly, tapered surfaces 39 and 39 are formed outside the intermediate pressing member 31.

A nut 41 is provided between the pair of intermediate pressure members 31 and 31. The nut 41 has guide portions 43, 43, 43, 43 which are coupled to each other in a movable state with respect to the guide grooves 33, 33 formed in the pair of intermediate pressure members 31, 31, respectively. Formed. Moreover, in the said nut 41, the surface of the up-down position of a figure becomes the taper surface 45 and 45, respectively. These tapered surfaces 45 and 45 are arranged to face the tapered surfaces 35 and 35 on the pair of intermediate pressure members 31 and 31 already described. In addition, the nut part 47 is provided with the nut part 47.

In addition, a pair of fastening members 51 and 51 is provided to insert the pair of intermediate pressure members 31 and 31 from the left and right directions in FIG. In these pair of fastening members 51 and 51, recessed parts 53 and 53 are formed, respectively, as shown in FIG. Tapered surfaces 55 and 55 are formed in the recess 53. These tapered surfaces 55 and 55 are arranged to face the respective tapered surfaces 39 and 39 of the pair of intermediate pressure members 31 and 31 described above.

Of the pair of fastening members 51 and 51, a through hole 57 is formed in the fastening member 51 disposed on the left side in FIG. 6, and a larger diameter is formed outside the through hole 57. The recessed part 59 is formed. In the pair of fastening members 51 and 51, a through hole 61 is formed in the fastening member 51 disposed on the right side in FIG. 6, and the outer side of the through hole 61 is further formed. A large diameter concave portion 63 is formed. In the pair of fastening members 51 and 51, engaging convex portions 65 and 65 are formed at the outer lower end portion of FIG.

Further, a bolt 71 is provided. The bolt 71 penetrates the concave portion 59 of the fastening member 51 disposed on the left side in FIG. 6 in the pair of fastening members 51 and 51. A hole 57 is inserted through the recesses 37 and 37 of the pair of intermediate pressure members 31 and 31 to be screwed into the nut portion 47 of the nut 41. The nut 41 is pulled toward the bolt 71 by screwing the bolt 71 to the nut 41. Thereby, the pair of intermediate pressure members 31 are formed by the interaction between the pair of tapered surfaces 45 and 45 of the nut 41 and the tapered surfaces 35 and 35 of the pair of intermediate pressure members 31 and 31. And 31 are pressurized and moved in a direction in which they are separated from each other (up and down directions in Figs. 3 and 6). The respective tapered surfaces 39 and 39 of the intermediate pressure members 31 and 31 and the respective tapered surfaces of the pair of fastening members 51 and 51 by moving the pair of intermediate pressure members 31 and 31. By the interaction of 55 and 55, the pair of fastening members 51 and 51 are configured to be pressed and moved in the direction in which they are separated from each other (width direction of the groove 9).

The operation will be described based on the above configuration.

First, as shown in FIGS. 4 and 5, a pair of intermediate pressure members 31 and 31 and a nut 41 are assembled. That is, the guide portions 43 and 43 formed in the nut 41 are engaged with the guide grooves 33 and 33 formed in the pair of intermediate pressure members 31 and 31, respectively. Thereby, the assembly shown in FIG. 4 and FIG. 5 is obtained.

Next, as shown in Fig. 3, the assembly is provided on the groove 9 of one of the pillar members 1, and a pair of fastening members 51 and 51 are provided on the groove 9, respectively. . In that state, the other pillar member 1 'is provided. By the installation of the other pillar member 1 ', the assembly and the pair of fastening members 51 and 51 are hidden in the other pillar member 1'.

Next, the bolt 71 is inserted into the through-hole 21 of the other pillar member 1 ', and the fastening member 51 disposed on the left side in FIG. 6 in the pair of fastening members 51 and 51. FIG. Through the recesses 59, through-holes 57, and the recesses 37 and 37 of the pair of intermediate pressure members 31 and 31, to be screwed into the nut portion 47 of the nut 41. To combine. The nut 41 is pulled toward the bolt 71 by screwing the bolt 71 to the nut 41. Thereby, the pair of intermediate pressure members 31 are formed by the interaction between the pair of tapered surfaces 45 and 45 of the nut 41 and the tapered surfaces 35 and 35 of the pair of intermediate pressure members 31 and 31. And 31 are pressurized and moved in a direction in which they are separated from each other (up and down directions in Figs. 3 and 6). The respective tapered surfaces 39 and 39 of the intermediate pressure members 31 and 31 and the respective tapered surfaces of the pair of fastening members 51 and 51 by moving the pair of intermediate pressure members 31 and 31. By the interaction of 55 and 55, the pair of fastening members 51 and 51 are configured to be pressed and moved in the direction in which they are separated from each other (width direction of the groove 9).

In addition, the coupling convex portions 65 and 65 of the pair of fastening members 51 and 51 are coupled to the coupling concave portions 11 and 11 of the groove 9, thereby obtaining a secure fastening state. .

According to the present embodiment described above, the following effects can be obtained.

First of all, the desired coupling state can be obtained with a small number of parts. Specifically, a desired engagement state is obtained by a pair of intermediate pressure members 31 and 31, a nut 41, a pair of fastening members 51 and 51, and a bolt 71. Therefore, parts management is easy and cost-effective.

In addition, the pair of intermediate pressure members 31 and 31, the nut 41, and the pair of fastening members 51 and 51 are covered by the other pillar member 1 'in a state of being installed in the groove 9. Afterwards, the desired coupling state can be obtained by simply screwing the bolt 71 through the opening 21 of the other pillar member 1 ', thereby facilitating the coupling work and thus reducing the labor force required for the work. Reduction and time can be shortened.

In addition, the pair of intermediate pressure members 31 and 31, the nut 41, and the pair of fastening members 51 and 51 are covered by the other pillar member 1 'in a state of being installed in the groove 9. Therefore, the stability during the joining operation is also sufficiently secured.

In addition, a firm coupling state can be obtained by the coupling structure of the coupling convex portions 65 and 65 of the pair of fastening members 51 and 51 and the coupling concave portions 11 and 11 of the groove 9.

In addition, since the pair of intermediate pressure members 31 and 31 and the nut 41 are assembled by the coupling structure of the guide grooves 33 and 33 and the guide portions 43 and 43, the position shift of both It is possible to prevent the back and the like, thereby ensuring sufficient stability during the joining operation.

In addition, since the pair of fastening members 51 and 51 are configured to be pressed at two positions in the upper and lower portions in FIG. .

Next, a second embodiment of the present invention will be described with reference to FIGS. First, there is one pillar member 101, and the pillar member 101 has a substantially square cross-sectional shape and a hollow shape. That is, the hollow part 103 is formed in the center part of the pillar member 101. The hollow part 103 extends and is formed along the longitudinal direction of the pillar member 101. In the cross-sectional shape of the pillar member 101, another hollow portion 105 is formed in four corners. These four hollow portions 105 also extend and are formed along the longitudinal direction of the pillar member 101.

In addition, grooves 109 are formed in the four side surfaces 107 of the pillar member 101. Engaging recesses 111 and 111 are formed at both ends in the width direction of the groove 109.

Arbitrary side surfaces 107 of the one pillar member 101 are joined in contact with each other from a direction perpendicular to the other pillar member 101 '. The other pillar member 101 ′ also has the same shape as the one pillar member 101. In the drawings, the same reference numerals are attached to the same reference numerals. Moreover, the opening part 121 is formed in the specific groove 109 'of the other pillar member 101'. The bolt mentioned later is operated through this opening part 121.

9, 10, and 12, in the other pillar member 101 ', a pair of fastening members 123, 123 are positioned in opposition. These pair of fastening members 123 and 123 are provided in the groove 109 of the arbitrary side surface 107 of the one pillar member 101 in the state which can move to the width direction of the groove 109. As shown in FIG. 9, 10, and 12, guide surfaces 125 and 125 are formed on the bottom surfaces of the pair of fastening members 123 and 123, respectively. These guide surfaces 125 and 125 are brought into sliding contact with the bottom surface of the groove 109. 9, 10, and 12, lower ends of the fastening members 123, 123, and engaging convex portions 127, 127 are formed at the outer ends thereof. These engaging projections 127 and 127 are engaged with the engaging recesses 111 and 111 of the groove 109 described above.

Moreover, the external shape of the pair of fastening members 123 and 123 has a shape that matches the inner surface shape of the hollow portion 103 'of the other pillar member 101'.

9, 10, and 12, a pair of nuts 131, 131 are provided between the pair of fastening members 123, 123. Taper surfaces 133 and 133 are formed on the pair of nuts 131 and 131, respectively. The inclination angle α of the tapered surface 133 is set to 20 degrees.

However, it is not limited to it as an example to the last.

In addition, in the pair of fastening members 123 and 123 described above, coupling recesses 135 and 135 to which the nuts 131 and 131 are respectively coupled are formed. Further, the nut parts 137 and 137 are formed in the pair of nuts 131 and 131, respectively.

Further, the bolts 139 are screwed to the nut parts 137 and 137 of the pair of nuts 131 and 131. By screwing the bolt 139 into the nut parts 137 and 137 of the pair of nuts 131 and 131, the nut 131 disposed on the side away from the bolt 139 is pulled toward the bolt 139. . As a result, the pair of nuts 131 and 131 are pressed and moved outward by the interaction of the tapered surfaces 133 and 133 of the respective nuts 131 and 131.

The pair of fastening members 123 and 123 disposed on the outer side of the pair of nuts 131 and 131 are pressed and moved outward by pressing and moving the pair of nuts 131 and 131 with respect to the outside. Then, as the pair of fastening members 123 and 123 are pressed and moved outward, the engagement convex portions 127 and 127 of the pair of fastening members 123 and 123 are engaged with the recesses 111 and 111 of the groove 109. ). By this, a firm coupling state is obtained.

The operation will be described based on the above configuration.

First, as shown in Figs. 10 and 11, the bolts 139 are screwed to some extent to the pair of nuts 131 and 131 to be integrated. Next, as shown in FIG. 10, the pair of fastening members 123 and 123, the integrated pair of nuts 131 and 131, and the bolt 139 are provided on the side surface 107 of one pillar member 101. Is installed on the groove 109. The other pillar member 101 'is installed to cover and hide the pair of fastening members 123 and 123 and the integrated pair of nuts 131 and 131 and the bolt 139.

This operation results in an appearance as shown in FIG. Next, the bolt 139 is further screwed onto the pair of nuts 131 and 131 using a jig not shown in the drawing through the opening 121 formed in the other pillar member 101 '. Let's do it. As a result, as shown in FIG. 11, the nut 131 arranged on the side away from the bolt 139 is pulled toward the bolt 139. At that time, the pair of nuts 131 and 131 are pressed and moved outward by the interaction of the respective tapered surfaces 133 and 133 of the pair of nuts 131 and 131.

The pair of fastening members 123 and 123 disposed on the outside of the pair of nuts 131 and 131 are pressed and moved to the outside by pressing and moving the pair of nuts 131 and 131 with respect to the outside. The pair of fastening members 123 and 123 are pressed and moved outward while sliding and contacting the guide surfaces 125 and 125 with respect to the bottom surface of the groove 109. In addition, the coupling convex portions 127 and 127 of the pair of fastening members 123 and 123 are coupled to the coupling concave portions 111 and 111 of the groove 109, thereby obtaining a firmly coupled state.

According to the present embodiment described above, the following effects can be obtained.

First of all, the desired coupling state can be obtained with a small number of parts. Specifically, a desired coupling state is obtained by a pair of fastening members 123 and 123, a pair of nuts 131 and 131, and a bolt 139. Therefore, parts management is easy and cost-effective.

In addition, the bolt 139 is screwed to the pair of nuts 131 and 131, and the other pillar member 101 'is mounted in the state where the pair of fastening members 123 and 123 are installed in the groove 109. Cover and hide it, and afterwards, the desired coupling state is obtained only by screwing the bolt 139 through the opening 121 of the other pillar member 101 '. We can reduce labor force and shorten time.

In addition, the bolt 139 is screwed into the pair of nuts 131 and 131, and the other pillar member 101 'is mounted in the state where the pair of fastening members 123 and 123 are installed in the groove 109. Since the cover is covered by the cover, the stability during joining is also sufficiently secured.

In addition, the action of the tapered surfaces 133 and 133 of the pair of nuts 131 and 131 and the coupling concave portions 127 and 127 of the pair of fastening members 123 and 123 and the coupling recesses 109 of the groove 109 By the coupling structure of 111 and 111, a firm coupling state can be obtained.

In addition, the pair of fastening members 123 and 123 are formed with coupling recesses 135 and 135 to which the pair of nuts 131 and 131 are coupled. The position of the pair of nuts 131 and 131 does not seem to shift, and a desired effect can be obtained more reliably.

In addition, this invention is not limited to the said 1st, 2nd Example.

For example, the shape of a pair of fastening members or nuts is not limited to those shown in the drawings.

In addition, various things can be considered about the structure of each part.

The present invention relates to, for example, a coupling structure of a structural material for joining both pillar members in a state in which the cross section of the other pillar member is orthogonal to the side surface of one pillar member. The present invention relates to a structure that can be easily attached to a structure and that it is difficult to loosen with respect to an external force, and is designed to obtain a rigid fastening force. It is preferable when joining, for example, when installing the installation stand of a machine tool.

1 pillar member
7 side
9 home
11 mating recesses
1 'one pillar member
7 ′ side
9 ′ home
11 ′ mating recess
21 opening
31 Medium Pressure Member
33 Guide groove
35 tapered sides
39 tapered sides
41 nuts
43 guide
45 tapered faces
47 Nut
51 fastening member
53 recessed
55 tapered sides
65 mating convex
71 volts
101 pillar member
107 side
109 home
111 mating recess
101 'one pillar member
107 'side
109 'home
111 'mating recess
123 Fastening Member
127 engaging convex
131 nuts
133 tapered surface
139 volts

Claims (8)

In the coupling structure of the structural member which couple | bonds in the state which attached the other pillar member perpendicularly to the side surface of one pillar member,
A pair of fastening members provided inside the other pillar member and movable in the width direction of the groove formed on the side surface of the one pillar member;
A nut mechanism disposed inside the other pillar member and disposed between the pair of fastening members;
A bolt bolted to the nut mechanism by operating from the outside through an opening formed in the other pillar member.
Equipped,
By rotating the bolt, the engaging convex portions respectively formed at the end portions of the pair of fastening members are pressed and moved in a direction in which the pair of fastening members are separated from each other by the action of the nut mechanism. A coupling structure of a structural material, characterized in that a coupling state is obtained by coupling to coupling recesses respectively formed in both widthwise ends of a groove of the one pillar member.
The method of claim 1,
The nut mechanism has an inner side of the other pillar member and is disposed between the pair of fastening members, respectively, and has a tapered surface facing the pair of taper surfaces of the pair of fastening members. And a pair of intermediate pressure members provided in a state where the tapered surfaces thereof are opposed to each other, and disposed between the pair of intermediate pressure members to face each tapered surface of the pair of intermediate pressure members. Consists of a nut with a pair of tapered surfaces,
The nut is pulled to the bolt side by screwing the bolt to the nut, and the pair of intermediate pressure members are pressed in a direction away from each other by interaction between the tapered surface of the nut and the taper surface of the pair of intermediate pressure members. And the pair of fastening members by moving the tapered surface of the pair of intermediate pressure members and the tapered surfaces of the pair of fastening members by moving the pair of intermediate pressure members in the separation direction. Combination structure of the structural material characterized in that to press and move in a direction away from each other.
The method of claim 2,
And the pair of intermediate pressure members move along the longitudinal direction of the other pillar member, thereby moving the pair of fastening members along the width direction of the groove.
The method according to claim 2 or 3,
A guide groove is formed in each of the pair of intermediate pressure members, and the nut is formed with a guide portion for movably engaging with the guide groove.
The method according to any one of claims 2 to 4,
A concave portion is formed in each of the pair of fastening members, and the tapered surface is formed in the concave portion, and the pair of intermediate pressure members and the nut are configured to be accommodated in the concave portion. .
The method of claim 1,
The nut mechanism is constituted by a pair of nuts which are formed inside of the other pillar member and are disposed between the pair of fastening members and face each other with the tapered surfaces provided.
By rotating the bolt, the pair of nuts are moved outward by the interaction of the tapered surfaces of the pair of nuts, thereby pressing the pair of fastening members arranged on the outside to be spaced apart from each other, Joining structure of the structural member, characterized in that for moving.
The method of claim 6,
The pair of nuts are stacked and arranged in a state in which the respective tapered surfaces are in close contact with each other along the axial direction of the bolt, and the nuts arranged on the side away from the bolt are pulled toward the bolt side by screwing the bolts together. And a pair of nuts move outwardly and move in a direction in which the pair of fastening members disposed on the outside are separated from each other.
The method according to claim 6 or 7,
Coupling structure of the structural member, characterized in that the pair of fastening members are each formed with a coupling recess for coupling the pair of nuts.

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